DE2811056A1 - IMAGE GENERATION PROCESS - Google Patents

Description

The invention relates to a method of generating images using an ion current modulating element like a photosensitive grain in the form of a grid (hereinafter referred to simply as the "control grid" is designated) with a large number of fine openings. In particular, the invention relates to a method for controlling the imaging conditions on the photosensitive body or similar recording media, which is also effective in the Bildzeuqunqsverfahren in which an ion current by means of one and the same primary electrostatic charge image is modulated many times.

The most well-known electrophotographic processes are used in direct processes such as the electrofox process and divided into indirect methods such as the xerographic method. In the Bildzeuqunqsverfahren in use

![/so

809839/0707

of the direct | 7 method is the record to be used : ■ ".-" ■ material A material that requires special treatment

: has been subjected, such as by coating a: photoconductive substance such as zinc oxide, etc. on 5 "jfr. ■ ^ the '^. u ^ calibration material. Because of this, the on the /" - ^' - ß & r * f ^ i ^ The image formed in colored recording material is low in brightness, and the image contrast on the surface of the recording material causes problems. Furthermore ':;'"Because of the special treatment, the recording material has a disadvantage in that it feels a little different compared to ordinary paper and appears thick and heavy. As in the image-forming process according to the indirect process as a recording material or image-receiving material If ordinary paper is used to form the desired image, the advantage is achieved that a satisfactory image with high image contrast is obtained. However, this indirect method has a disadvantage that in the transfer of:. ' Tpnerbilds on the recording or image receiving material this comes into; contact with the surface of the photosensitive body and, moreover, when removing excess toner, a cleaning device such as a brush, a resilient blade and the like comes into forceful contact, brought to the photosensitive body 25 -. "-. '" - "is -v so that its surface at each m cleaning process is damaged. As a result, the life of the expensive photosensitive body is shortened, causing an increased image forming cost.

To eliminate the various disadvantages

. -: - ..:;.; of the known electrophotographic process, a process is described, for example, in JP-OS 48/59840: γ ^; (which corresponds to U.S. Patent 3,713,734). This well-known

; The electrophotographic process provides for the use of one 35 ■: - '": Control grid in the form of a network or grid with

ORIGINAL INSPECTED

- 4 - B 8803

a multitude of finer openings with regard to the mesh size before. The principle of this method is that on the control grid an ion current to form a electrostatic charge image on the recording material is modulated, after which the recording material bearing the charge image is developed. That is, according to this In the electrophotographic process, there is no need for developing and cleaning the control grid, which is the conventional one corresponds to photosensitive body. Thus, according to this method, the control grid is advantageous usable over a lance period. In particular, as described in Japanese Patent Application Laid-Open No. 51/341 (that of U.S. Patent Application No. 771309 and DE-OS 2 4 29 303 corresponds) the method both in terms of durability of the Control grid improved with success as well as image generation by repeatedly using one once formed primary electrostatic charge image by a multiple compared to the generation in the conventional method realized (this repeated process of reproduction hereinafter referred to as "repeat copying"). This procedure is not explained in detail here, however, its basic principle is folaendes: First is the control grid is constructed in such a way that a photoconductive material is placed on an electrically conductive base or core material is stacked so that the core material is covered leaving a surface side exposed, and over the surface an insulating material is attached to the electrically conductive material coated in this way. The image generation takes place in such a way that one on the control grid formed primary electrostatic charge image is used to modulate an ion current that is applied to a chargeable material is directed; as a result, a secondary electrostatic charge image is obtained on it Chargeable material can be paper for electrostatic recording or a Troirmel element with a

- 5 - B 8803

Union insulating cover layer used as a recording material (insulated drum). In the case of using the paper for electrostatic recording, it becomes directly developed and fixed by means of known measures and thus used as a reproduced copy. In contrast, in the case of using the insulated drum the secondary charge image is developed on the drum, after which the developed image is like on image receiving material ordinary paper fed separately is transferred, which is then fixed and serves as a reproduced Kooie. Therefore, the insulated drum is up by removing the the toner remaining after the image transfer is repeated usable.

In the case of an image forming device in the case of repeat copying is performed using the control grid, such as in a reproduction machine there is a case that due to various changed factors such as a difference in background brightness an original to be reproduced, changes in the environmental conditions of the reproduction device etc. the conditions in forming the primary electrostatic charge image from a suitable one Deviate from the range that was set in advance.

If under such conditions the image generation actually does is carried out, a fogging takes place on the overall image, so that the image contrast is reduced, or else in contrast, erasing the dark part of the image (especially thin lines) so that an ambiguous Image results. In this situation, a usable image can be obtained by setting different reproduction conditions again such as the amount of image irradiation, the amount of electric charge on the control grid, and so on thorough visual examination of the generated image and then by re-establishing the primary electrostatic

S09839 / 07Ö?

- 6 - B 8803

Charge image can be achieved. This way to achieve However, more usable pictures is not advisable as it just takes a considerable amount of time to set the complicated Conditions for such usable picture reproduction is wasted, but also the durability of the control grid due to the increased frequency of the imaging processes for the primary electrostatic Charge image is trimmed on the control panel. About that In addition, changes in the imaging conditions for the primary charge image make the basic conditions for imaging unstable or uneven.

With regard to the differences occurring in the known electrophotographic reproduction process Problems of the invention is based on the object to provide an image forming method in which the Various disadvantages inherent in conventional methods are eliminated and with which the formation of a High quality image is accomplished.

The method according to the invention is intended to make a change of the secondary charge image to a more favorable state without a change in the conditions of formation of the primary charge image with respect to the ion current modulating element enable.

Further, the method of the present invention is intended to smoothly perform the formation of a clear image regardless of changes in the above-mentioned factors in the image forming apparatus thereby

. That these variable values are compensated for in the formation of the secondary charge image without the original charge image is newly generated.

Furthermore, the invention is intended to provide an image generation

809839/0797

;; ■■ '-.' ■ - 7 - B 8803

method can be created in which no undesired fogging phenomena are caused on the image formed even without applying a bias voltage to the developing device.
-.V "'_ ■■ - ■"' - ■: ■ ... "-

Furthermore, should an advantageous Bilderzeugungsein-; direction and advantageous imaging conditions are specified for the device, the device for carrying out the imaging method easy _on-TO: to be built, and allow accurate image _control: should.

The object is achieved according to the invention as follows: When a stream of ions hits a recording material with Charge retention properties by means of a modulating element

: is applied which modulates the ion current in the form of an image, the electrostatic charge image to be formed on the recording material is controlled to a satisfactory state such that the surface of this recording material is charged to a predetermined potential in advance the method can, for example, even when deterioration of the ion current Modulierelements or a change in the quantity of the modulating ion satisfactory; secondary electrostatic latent image is formed by applying the charge potential on the surface of the up set ⁵ / drawing material without changing the conditions for the primary charge image will. Further, for example, while performing the repeat copying, if the electric field for the modulation changes due to the deterioration of the primary charge image and the amount of the modulated ions has been changed, at that time, to continue the repeat copying. conventional methods reshaped the electric field for the ion modulation. According to the invention, however

2811Q56

- 8 - B 8803

the part of the modulated ion quantity changed by the change in the modulating electric field thereby be compensated that the charging potential is formed on the recording material. Because of this, can the time and effort required to "reshape the electrical." Field for the modulating element is omitted even if when the amount of the modulated ions changes in the repeat copying, which is the case with the conventional methods occured.

Another advantageous feature of the invention The method is, for example, that when the recording material is uniform in advance with negative (-) polarity is charged and then on the recording material under modulation an ion current positive (+) Polarity is directed, a secondary electrostatic charge image can be formed

that has opposite polarity in the light and dark parts of the image. Because of this occurs even if a developing bias is brought to the ground voltage at the developing device assumes the simplest structure, no haze appearance, so that the secondary charge image can be clearly developed on the recording material can.

As a device for uniformly loading the recording material A corona discharger is common prior to ion current modulation. There are therefore different Method for controlling the amount of charge, such as by changing the amount sent to the corona discharger applied voltage or by using a corona discharger with a grid device whose bias is changed will. In particular, the method in which the grating is used to make the recording

509639/079?

- - 9 - B 8803

to bring material to a desired potential. The reason for this is that from the corona discharge electrode always a constant amount of corona ions is generated, from which by means of the close to the recording material attached grids which are placed on the recording material -.--- - the appropriate amount is set, creating a uniform and very precise charging potential can be built up.

; This way it is over with the modulated ions to the ion current modulating element and the potential of the im

pre-loaded recording material possible, the secondary Charge image in an extremely satisfactory Condition to train. Furthermore, by means of the method described above, it is always possible to find an equal-ί5 to develop a moderate picture without different conditions for the device to form the primary charge image or to change the bias of the developing device to change.

Further, the developing device can be considered to drift in an electrical manner in accordance with changes in the secondary charge image, so as to To change the bias on this development facility,

- ■ '_- "■■: ■ thereby as a ^result, certain clear picture is obtained..

.-. ". ■ - ■;} .. ■ In addition to the EIe -.'-.- iäenten as described in JP-OS 49/121544 which the ion current modulation is carried out using a slot-shaped element, a control aitter with a Large number of fine passage openings can be used.

Furthermore: can be used as a basic structure for the grid device - the discharger for charging the recording material to a certain fixed potential, a metal plate 5 can be used in which a plurality of narrow slots or

609839/075?

- 10 - B 8803

a plurality of fine openings is formed. The (hereinafter simply referred to as "grid") grid device is in the corona discharge device on the side of the Recording material attached and arranged out of contact with the recording material. The electric The potential on the recording material becomes uniform as a result, that the amount of the above-mentioned corona discharge device through the grating onto the recording material arriving coronaions is controlled.

As one form of the above-mentioned recording material, a material which is chargeable is possible Has a layer on the surface, such as an insulated drum, photosensitive drum or the like, and that with the attachment of a developing device, a transfer device and a cleaning device is used repeatedly. Regarding the design, of course, it's not just the Tronunel shape, but the shape of an endless belt or a long wound belt is also possible. Another shape for the recording material is that the material itself is in the form of a sheet that is used for developing and fixing is used.

As an advantageous embodiment of the corona discharge device The grid to be attached can be a grid made up of a plurality of thin wire electrodes is constructed. The distance between adjacent thin wire electrodes is preferably in the range to choose from 0.5 to 1.5 mm. The distance between these electrodes and the recording material should be substantial be equal to the distance between adjacent electrodes, while a width 1 of the Koronaentladunaseinrichtung with respect to the direction of movement of the recording material in accordance with equation 1 = 4 vdK / t 5 (in mm) is selected, in which d is the distance between one

809839/0797

- 11 - B 8803

on the adjacent electrodes for forming the grid in mm, t is the thickness of a chargeable material of the recording material denotes in / µm, K denotes the dielectric constant of the chargeable material, t / K denotes the effective thickness of the chargeable material in / µm and ν denotes the speed of movement of the recording material in cm / s.

The invention is illustrated below with the aid of exemplary embodiments explained in more detail with reference to the drawing.

Fig. 1 is an enlarged cross section of a control grid and is used for explanation of an embodiment.

FIGS. 2-4 are each schematic representations for explaining the process procedure for the formation of a primary charge image by means of the control grid shown in FIG. 1.

Fig. 5 is a schematic illustration to explain the process of forming a secondary charge image using this control grid.

Fig. 6 is a cross-sectional view schematically showing shows the construction of a reproducing apparatus in which the control grid of Fig. 1 is used.

Fig. 7 is a cross-sectional view showing an embodiment a corona discharger

-: shows the first set up for the

Represents imaging process.

- 12 - B 8803

Fig. 8 is a graphical representation for

Explanation of changes in a potential curve with which a potential change on an insulated drum in the vicinity of the corona discharger

Fig. 7 is shown.

Fig. 9 is a graph showing the

Relationship between a grid voltage and a grid width in the control

shows a charging potential on a chargeable material.

10 is a cross-sectional view schematically showing the structure of another embodiment

form of a facility for the imaging process shows.

Fig. 1 shows an embodiment of a control grid for use in the imaging process, wherein the structure of the grid is shown schematically in enlarged cross-section. According to the figure is the control grid constructed so that on an electrically conductive material 2 such as a metal mesh or the like. With a large number of fine openings a photoconductive material 3 and an insulating material 4 provided as a cover layer or outermost coating are stacked in such a way that a surface side of the electrically conductive material is exposed.

2 to 5 show, as an example, a process for forming a Ladunosbild with the help of Control grid 1, its detailed description with regard to on the prior publication is omitted. In the present description, an example is explained at which the control grid 1 has the property that a hole or deficiency electron is injected into the photoconductive material

809839 / G737

- 13 - B 8803

will. That is, it is believed that the photoconductive "" - "". "Material 3 a semiconductor material such as selenium (Se), its Alloys, etc., in which the deficient electron is the main carrier.

Fig. 2 shows the result of the application of a primary voltage, in which the insulating material 4 of the control grid 1 is charged uniformly in negative polarity {-) by means of a known charging device. By This charging process is carried out via the electrically conductive material

2 the hole or defective electron in the photoconductive material

3 initiated and at the interface near the insulating material 4 formed a Ladunasschicht. In the figure, 5 denotes a corona discharger.

■; - ;. ■ '■■ ■ -; ..

The. Fig. 3 shows the result of almost simultaneous application of a secondary voltage and imagewise exposure in which for the application of the secondary voltage; a corona discharge is used with a voltage that : slH of the power source is achieved by superimposing a bias voltage of positive polarity on an alternating voltage.

Instead of the alternating voltage, the voltage to be applied can also include a direct voltage with the primary voltage be of opposite polarity. If the dark attenuation of the photoconductive material 3 is slow, need the application of the voltage and the image-wise exposure not to be carried out at the same time, but can be carried out on one another. to be carried out below. In the drawing, 6 denotes an original image to be reproduced, L denotes a light partial area the same and D a dark portion, while 7 denotes light rays and 8 denotes a corona discharger.

4 shows the result of a total exposure of the control grid 1, in which the surface potential

■ 809839/079?

- 14 - B 8803

of the control grid 1 suddenly only at the "dark part of the same" to a surface charge level of the insulating material 4 perDortional potential changes, so that the original charge image is thereby formed. In the Drawing 9 denotes the light rays.

Fig. 5 shows a state in which an ion current has been modulated by means of the above-mentioned primary charge image, whereby a positive image of the original has been formed on the recording material. In the drawing, 10 denotes a corona wire and 15 a recording material which has an insulating layer 12 and an electrically conductive substrate 11 for holding charge. 13 and 14 denote power sources. The recording material 15 is arranged in a position in the vicinity of the side of the control grid 1 provided with the insulating material 4 in such a way that, using a potential difference between the corona wire 10 and the electrically conductive substrate 11, an ion current controlled by the control grid 1 ae from the corona wire 10 reaches the recording material or the insulating layer 12. In this case, the charge of the primary charge image on the control grid 1 acts on the bright sub-area of the original image (with the solid line (Λ marked) to hinder the ion flow, while the dark sub-area of the original image acts (with the solid line The electric field shown in FIG. 3 acts to allow the ion current to flow, thereby forming the secondary charge image, which is a positive image of the originals, on the recording material 15. When the control grid 1 having the structure described above is used, the primary charge image is formed on the Insulating material is formed so that it becomes possible to increase the electrostatic contrast based on the amount of electric charge to a very high level

- 15 - B 8803

the decrease in the charge image charge that continues to develop can be reduced to the smallest possible value, the repeat copying will be in a number of times possible, which is larger than that of the conventional recording material is. When the polarities of the power sources 13 and 14 in Fig. 5 are reversed, they arrive negative ions through an area corresponding to the bright partial area of the image, as a result of which on the recording material 15 a negative image is formed. When the control grid 1 is constructed so that as a photoconductive Material 3 a semiconductor material such as cadmium sulfide (CdS) whose main carriers are electrons is used, so that electrons are injected into the dark area of the original image is, of course, in the training of the primary Charge pattern opposite to the primary voltage in the example described above, while those to be applied in the formation of the secondary charge image Voltages all have opposite polarity.

In the following there will be explained a reproducing apparatus in which the control grid having the structure shown in FIG is used. The one in the drawing as an exemplary embodiment The image forming apparatus shown is a reproduction apparatus 16 which, using the charge image forming processes as explained with reference to Figs. 2 to 5, a reproduced image on ordinary Paper generated. The respective parts of this reproduction -. device are shown in the figure in cross section. In the 6 denotes 17 ″ an outer wall or an outer housing of the reproduction device 16, on the upper side of which an original image is displayed Position table 18 made of transparent material such as glass or the like. Is provided. This master support table 18 is firmly attached, while the image-wise exposure of a control grid 19 by partially moving an opti-5 see setup done. This optical device is

809-839 / 0787

- 16 - B 8803

built in a known way; the optical device has a first mirror 20 and an original illuminating lamp 21 from their positions shown with solid lines into their positions shown with dash-dotted lines Positions on the far right are shifted at a speed V so that they cover the entire length of the original support table 18 back. On the other hand, the surface of the original image is scanned at the same time as the displacement first mirror 20, a second mirror 22 at a speed V / 2 from that shown in solid lines Moved position to its position shown with dashed lines on the far right. That by means of the The first and the second mirror 20 and 22 scanned image is via a lens system 23 with a diaphragm mechanism and a fixed mirror 24 directed to the control grid 19. The control grid 19 is drum-shaped in the Constructed way that the surface with the externally exposed electrically conductive material to the inside of the cylindrical Control grid is directed. In the vicinity of the control grid 19 is one in the direction of rotation of the control grid 19 Charge image formation means arranged. In the drawing, 25 denotes a pre-exposure lamp used for this purpose , the photoconductive material of the control grid is in a constant uniform photohysteresis state bring to. 26 denotes a corona discharger which is the means for applying the primary charge and which charges the rotating control grid 19 to a sufficient voltage level. 27 denotes another corona discharger, which represents the device for applying the secondary voltage and on which the exposure with the original image takes place while the electrical charge applied by the corona discharger 26 is removed from the control grid 19 will. For this purpose, this corona discharger 27 is constructed in such a way that a shielding plate is optically visible on its rear side 5 is open. 28 denotes a lamp for total exposure

809839/0797

■ - ■ "■■ - 17 - B 8803

or overall exposure of the image with which the control grid 19 is uniformly illuminated in order to rapidly increase the electrostatic contrast of the primary charge image.
In the manner described above, the primary charge image can be applied to the control grid 19 with a qroßen electronic _■:.. "Static contrast be formed A arranged within the cylindrical control grid 19 corona discharger 29 is used, spurious electric charges to
remove 'produced by a modulating corona discharger 31

adhere to or accumulate on the control grid 19 during the repeat copying. 30 denotes a Counter electrode, which is arranged in opposition over the control grid 19 ′ to the corona discharger 29. The counter electrode 30 is used when removing the

electrical charge to prevent erasure of the primary charge image on the control grid 19.

-.-. "■ -,": The secondary charge image is formed by means of the modulating corona discharger 31 on an insulated drum 32 which is a recording material rotating in the direction of the arrow. The insulated drum 3 2 is constructed in such a way that on an electrically conductive substrate 33
an insulating layer 34 is stacked. This insulated drum works in such a way that a tension between

the electrically conductive substrate and the electrically conductive

; - .. "■" de material of the control grid 19 is applied and the
modulated corona ions are conducted onto the surface of the insulating "layer 34. This is done in this way on the
The secondary charge image formed by the insulating layer 34 is developed into a toner image by means of a known developing device 36. The toner image is then transferred to image transfer or image receiving material 39, the
has been transported to an image transfer station 3 in synchronism with the toner image. The insulated drum 32 is

- After completion of the image transfer process by means of a

809839/0797

- 18 - B 8803

known cleaning device 37 cleaned to remove residual toner, after which it is cleaned by means of a corona discharger 38 is brought to a uniform surface potential for the subsequent reproduction process. As will be explained later, the yora-called corona discharger 38 is used in terms of its discharge amount by means of a Grid 38a controlled. Its control is also to a certain extent by adjustment of the corona discharge electrode applied voltage possible. By using the grid 38a as in the present embodiment fine adjustment of the applied voltage is possible, reducing the surface potential on the insulated drum 32 can be precisely adjusted to a desired potential.

As the developing device, either a dry developing device or a wet developing device can be used. A blade, a brush or the like can be used. That to the image transmission station 3 5 to be transported image receiving material 39 is loaded in a cassette 40 and is sheet for Sheet separated or detached by means of a roller 41 and a release pawl 42, the separated in this way Sheet is transported with registration rollers 43 in accordance with the position of the toner image. In the drawing 44 and 4 denote 5 transport rollers, while 4 6 denotes a corona discharger for the image transfer, which is used for this purpose serves to apply a bias voltage to the image receiving material 39 in transferring the toner image. After the image transfer the image receiving material 39 is detached from the insulated drum 32 with the aid of a release pawl 51 'and closed a fixing device 47, where the toner image is fixed by means of a heating device 48. That Image receiving material 3 9 with the image fixed in this way is conveyed to a receiving table 50 which has the

809839/0797

- - 19 - B 8803

finished image receiving material. If that Repeat copying is to be carried out, the process need only be repeated after the formation of the primary load image so that a high speed reproducing operation becomes possible.

In the image forming process, the surface of the insulated drum 32 which is the recording material represents, by means of the corona discharger 38 before the formation of the secondary charge image to a predetermined potential loaded. Therefore, in the embodiment shown in Fig. 6, the amount of corona discharge from the corona discharger becomes 38 is varied by controlling the voltage applied to the grid 38a; this becomes the secondary Charge image formed in a corresponding state. The reasons for the inaccuracy or inadequacy of the primary electrostatic charge image can be roughly divided into two reasons. The first reason lies in the case that an original image with a colored or colored or tinted background is used as a Image is to be reproduced with an uncolored background. In general, the training conditions are based for a primary normal or reference charge image, which from the start with. the reproduction device has been set, 5 on a template with a non-colored background.

In such a case, therefore, fogging (coloring) appears at the background of the reproduced copy,. .. which represents the finished picture. As a countermeasure against the animal phenomenon, the potential of the recording material is made different from a potential by which the looping occurs without adjusting the bias of the developing device; in this way, the desired fogging in the reproduced copy can be eliminated while maintaining the bias of the developing unit. The second reason occurs in ^ i ^F ^ ¹³ - / ^a / that the physical conditions like that

809839/0 797

INSPECTED

-20- B 8803

Corona discharge, the electrical resistance of the control grid etc. change due to environmental changes such as changes in temperature, humidity and the like, whereby the state of the primary electrostatic charge image changes. Even in such a case where the primary electrostatic charge image changed so as to cause a fogging phenomenon can be reproduced Copy in proper condition can be obtained if the potential of the recording material is in front. the training of the secondary electrostatic charge image is changed.

If, in contrast, the primary electrostatic charge pattern changed in such a way that there is a tendency for the image to be erased, even then cannot be usable or adequate Image can be obtained when the potential of the recording material is changed. Taking this into account, it is it is better that the normal conditions for the formation of the primary electostatic charge image in the reproduction device are maintained in this way move so that there is a tendency to fog for a commonly occurring range of change. if

^ O now the potential on the recording material before training of the secondary electrostatic charge image is shifted according to the above, therefore, the primary electrostatic Charge image, without being erased, can actually be kept in an adequate state even if the conditions are met for the primary electrostatic charge image so that there is a tendency to erase the image. There however, the normal conditions are still in a state in which fogging tendency occurs when the surface potential of the recording material is set according to the above, it becomes necessary by changing and Adjustment of the potential on the recording material to shift the potential that causes fogging to occur caused.

8G9839 / 0797

; ^: -; ' ^:: TQSB a -21- _ _oS> β 8803

In the following, a specific facility for training

-S'SBSJinz ^: s3 ^ B s; hi ϊ θ v; a bn.üi: / · ;;.;: · - '. v ^r ">::;> l-.λ ι: γ>'·" Ίο "itu., ραχ / Ε ^ Λ Jnoarovio" formation of the surface potential on the recording material 'Ciiräijjxi ^ ri &' iBV olvj firspfi ^ Ti.oirl ^ vv :: ■: /. ;;, JV, vn: j rev hniri. ^ rr, do;.; - '"3:'. corresponding to the Image forming method explained;

. "- ■; -" ■ The simplest setup is to use a

■ iiais rrioh "-isd ■ ·. IJ-iV ¹ ? N ^ J ^f v ;; - r- .? ■ -« ■ :: <>; ii m ': ^ ··. -.Fs.0.0 · ; -vivv - ": M"; .: · - to use conventional corona dischargers, to control a voltage applied to them and thus to set the charging potential of the recording material. Bine preferably to the

Corona discharge electrode voltage to be applied is a voltage -ι- «". -So 5 tiffi / bxiclBi'Ä -3 £ i £ - JO ";;; IsO "x ?;""-: * -. ■■ ;: " ac \ '^ ϊ. · ~'. <v \ £ :: ·; - X -'-;t; -.: c ' ^{r iU} the polarity of which is opposite to the voltage of the modulated corona ions and which puts the recording material in a state of charge with the charge by the modulated Ions offset opposite polarity, thereby increasing the potential

■ ... "- .; ■.> ..- · C- ^ i - ii'S", wsd "ϊί" · 3-ίί: νπνΐΓΐ? *: - Λα i; ii ^r >"-:;:;"■ .-- ■ - £ --.--- i. - ^1,. ^ o ^ .- - ^ - ^ ^t.:? '--- Λ- the background area of the picture and that at the picture area get the correct opposite ratio.

- """J- -..-- if-Si-, lsi - Or vDSSjSiTiÖ Π. S- ^ ί * ' ⁿ J Λ''' j D. ^ ;: Oi iOf>" ^f «-«. b? I. WJ: ^ ;: '. .; \ "

If that with such a potential on this way

"-'-," - .r- *. ^! 'i ".-" i35. nii-.Jrr ^ ^ Dni-bsdism -c.VT ->^lb:;. ;; ί) ^ ";: -> γ- ^!: ·;. · κ - .: ~ ^ Ί : π £>: .-" _, ϊί--. <> - the image formed on the recording material is developed, a clear reproduction free from fogging can be obtained.

^ r ^ fwhi-iijs? nsbns si ^ ^^ i / ia ^ r ^ -ri _^:.; ^ ii.c ::: Πΐ-ifs i: / ^r i H ^ n. re -ΐν); ^> v " - '■'

image can be achieved. The one on the discharge electrode can do this. - KTiS ^? ■, ir: a * t &sci; 3r? I.ni ^ liii «.."? " - ^ nJ:?: "- ·: .-;:.." ^ - r. i ^ ^; : about r; r. · - '. r ■; -. ·. of the conventional corona discharger known as yorgen

«*; WC.i, .itfSi.? A -"S-'t ⁴ ST ¹ "XO ^- V * Xij t'-tii j / n" i * -v "->. '"Ii-' ^f i "-ir-" O "'" ϊΐ? Λ'-;'ϊ:'Γ'ίί / ^{Γ !.} "if;. ·;. * 7>'' ^s S ^ i '■" ■ - "- "

Electricity doesn't just take the form of a "direct current" of an individual

Have polarity, but also the form of a superposed current of a _{r r} W ^ eqhse \ current and a direct current, the voltage of the direct current ^ is controlled to adjust das'Potential on the recording material. Furthermore, a method for changing the amount of discharge consists of such a conventional cofona discharger, in addition to the method of changing the voltage applied to the aforementioned discharge electrode, in changing a voltage applied to a shielding plate of the corona discharger.

. . "■■: ■: '- ■ ^" ivwv iiäiJ Lbs'x ^ s Bi ^ sXiXiV ^' I "~ i /; ^ '- : · /' - ^r :?. 2 λ: - ·.: ■ * <"". ■ -ν - ', - "-":? ■ --.-? -: "· αν ί .." - ■■.:? R ^ r? J'5 ^r As. Loading device instead of the Kprona unloader

there are different types such as a roller charger, a friction charger with one brush-shaped element and the like. Although this touch and friction chargers not for charging are suitable for a high voltage of up to a few thousand volts,

INSPECTED

C 03 S α

28ΠΟ56

-22- B 8803

can they fulfill their purpose well if they are used to build the surface: ent jraTs "des AufzeirchYiung ^ riia ^ ri ^ ais ^: 'in the range of up to a few hundred ⁱ vol £ ^c v € i $ inde € ^lj ? ^os '~ ^x '

As a preferred "wäKi'endes" Vef

tiä £ s "

Charging "des Oberflächeripötentiä £ s" deäι AüSzeichnunglittateriäis 'to a certain "desired' Poten ^ iäi'kätine'in-KÖtrohälntiaä with a grid" are used ': ~ In the following ,'daKIB ¹ -both the method'"is used to" Laaüng "'~ äes "Auf z'ei6hnüngBmäteriä $ s ^s · - using" a ^ äefärtigeh' Koronäentiäders- with a ^ '

Lattice as well as the structure of a ^J 'such "' discharger in eihzeinen" described. ""''"" ■■ - ■ ^iJ · '' ----- ■ '· - ■ -

FIG. 7 shows a QuefschnTtt MneS ^ embodiment of a suitable for the "image production process ^{a :} - ~" corona discharger; "FIG." in this'"hasa" the "En ^ ilräder -3-east" ^{2 Irr:;} -Fig. 6 corresponding discharger 51 in two stages corona discharger for a first and a second corona. "In'de'ir * drawing, the discharger" 51 has a first "Kbrbnaentlädüngskämm1ir ^> '5 * 2 ^;; and ^? A second corona discharge chamber" 53, in soft at "respective discharge electrodes 52a and 54 respectively a" HbfehVpähriunV "with" mutually different polarity "is excited / "'"'' ^: '~" ^! '^'

55 denotes an outer wall Γ which forms the EntTäiier ", in which the first chamber 52: and the second chamber 53 are constructed as · ^{0 !} ~~ ' individual unloaders of the unit'and" dei ^; An inner partition 56 is divided into the first chamber 52 and the second chamber 53. Of course, this first and this second discharge chamber can be separated independently in advance. _t .places must be appropriate. In the drawing, a reference number 57 in the "second Kbfotiäentlädüngskäftimir" 5 ^: 3 on the side facing the insulated drum 32 "'includes a' Glfctef, which is connected to an arbitrarily selected potential for controlling the surface potential of the insulated drum 32. "''.' ~ '''''~''''''' ^''''''''^{■;"" '■: ^: -: -:} - l ^<- ■' - '

Ash '■: · ; i

-23- B 8803

In the reproducing apparatus 16 in Fig. 6 using this corona discharger 51, it is assumed that a cadmium sulfide resin or CdS resin dispersion layer is used as the photoconductive material of the control grid 19 is so that therefore to the formation of a positive secondary Electrostatic charge image are generated by the modulating corona discharger 31 corona ions of negative polarity. Under under these circumstances is the discharge polarity on the corona discharger 51 is selected so that a positive voltage is applied to the discharge electrode 52a and a negative voltage to the discharge electrode 54 is created. Here, since it is sufficient that the corona discharges generated from the corona discharge electrodes 52a and 54 are essentially opposite in terms of polarity, a voltage superimposed with a bias voltage can be used as the applied voltage Viechsel tension can be used.

/ If in the secondary charge image the dark area of the original image has negative polarity is in view of preventing that which occurs as a result of the image development It is preferable to keep the light part of the original image at positive polarity. If in contrast in addition, the bright sub-area relates to the secondary charge image with zero potential or a negative potential forms the dark portion must to prevent fogging A bias voltage can be applied to the developing device, for which purpose the developing device is entirely of the main body must be insulated; this will make the attachment of the developing device in the reproduction apparatus is complicated. In the image forming method, however, it is also possible to use the Polarity of the second electrostatic charge image control that the dark sub-area and the light sub-area of the original image are polarized directly opposite one another, so that a good image is obtained by grounding the developing device. That is, it is sufficient to have one Voltage with the polarity of the at the corona discharge electrode 54 applied voltage of opposite polarity to the grid 57 of the corona discharger 51 to apply. In this

809839/0797

-24- B 8803

In this case, the potential of the insulated drum 32 changes as shown in FIG Time is applied. Here, too, the explanation is made for a photosensitive material of the control grid in which cadmium sulfide (CdS) is used. The surface potential of the insulated drum 32, which, due to the negative corona discharge for image transfer, _{assumes a potential V 1} , which at the time of this transfer process has been applied to the image receiving material by means of the corona discharger 46 for image transfer, first takes a positive corona discharge in the first corona discharge chamber by means of the discharge electrode 52a and is converted into a positive potential V n. Thereafter, the insulated drum 32 at the position of the second corona discharge chamber receives a negative corona discharge from the discharge electrode 54 so that the potential V "is converted into a potential V ₃ for the background portion which is lower than the potential V" and for development suitable is. For this purpose, it is sufficient to apply a voltage V, which is towards the voltage V 1, to the grid 57 instead of the voltage V 1. The potential V ₃ is determined by the developer used in the developing device and is usually zero to 100 V or the like. The potential difference between the voltages V. and V ₃ depends on the shape of the grid 57 and its setting position. If the linear interval or the linear spacing of the grid is very small, the relationship between the voltages V. and V becomes opposite to that shown in the drawing.

The grid 57 can be made in different shapes, such as by being thin Wires extending parallel or non-parallel to the corona discharge electrode 54, the thin wires in the form of a net or the like. The following explanation

809839/0797

: -25- B 8803

of the grid is done using an example in which the wires

The most important factors in this grid 57 are the distance d- between the grid 57 and the insulated drum 32, the distance d \ between adjacent grid wires and the area over which the grid 57 extends, ie , the width 1 of the arrangement of the grid in the direction of rotation of the insulated drum 32 (hereinafter referred to as the "grid width"). Although the grid 57 can be considered, it is only at a central part or more on one side in the of a predetermined grid width 1, experimental results have shown that, in terms of increased uniformity of the potential after the charge has been removed, no significant effect or narrowing of the grid area is achieved if the arrangement of the grid 57 is changed > j between the grid 57 and the drum 32 and the distance d i between mutually adjacent grid wires have essentially the same values. If the distance d.

assumes a value 1.5 times or larger, and particularly 2 to 3 times larger than that of the distance d-, the amount of electric current flowing to the insulated drum 32 via the grid 57 is considerably reduced. Because of this, when setting the grating 57 to a ratio of 1.5 or more, the grating width 1 must be selected to be very wide. However, if the grid width 1 is selected to be wide enough, there is an effect that the period of time during which the drum surface is exposed to the corona discharge is increased and the potential of the insulated drum 32 becomes very uniform. On the other hand, if the distance d is 0.7 times _; half or less of the

Distance d ~ , the control effect of the grid on the potential is reduced and the changes or fluctuations: the potential after passing the corona discharger become large. In order to achieve an advantageous result in practice, the distance between the adjacent grid wires should preferably be selected to be 0.5 to 1.5 mm or the like. . ;

; 8098 39/07 9 7

-26- B 8803

Fig. 9 is a graph showing changes in potential on the chargeable material due to the corona discharger for the image forming process. The experimental results shown in this graph are, as an example, those for the corona discharger shown in FIG. In the graph, the ordinate represents the surface potential of the insulated drum in V, while the abscissa represents the grid width of the corona discharger in mm, and V * represents a voltage applied to the grid 57 in V. In the above-described corona discharger 51, when the distance d ₁ becomes larger than the gap or distance d_, the surface potential of the insulated drum changes as shown by the curve X. In contrast, when the distance d. is less than 0.7 times, half or less of the distance or space d_, the change in potential corresponds to the representation by the curve Z, with the time to a saturation state of the change in potential being delayed during a rapid change in potential on the insulated drum and moreover, the uniformity or stability of the surface potential of the drum is deteriorated from the case where the distance d. is greater than the gap or distance d ₂ . In accordance with the general consideration of the above test results, the distances d .. and d ~ should preferably be chosen to have essentially the same values. In contrast to this, the time t (in s) required for the discharge is proportional to the circumferential speed ν of the insulating drum (in cm / s), the electrostatic capacity of the insulating layer 34 on the insulated drum 32 and the distance dj (which corresponds to the distance d " is proportional), and inversely proportional to the strength or power of the corona discharger or the corona discharge chamber 53 and to permissible fluctuations in the potential after the removal of the charge. The permissible fluctuations in the potential at the insulated drum 32 should be in such a range that the developed image is not influenced after development

809839/0797

-27- B 8803

caused. With the device according to those described above Embodiment · the fluctuations should preferably be in a range of approximately 10 to 20 volts. By inserting of the aforementioned allowable range for maintaining high uniformity of the image can increase the potential of insulated drum can be changed in precise accordance with changes in voltage applied to the grid. On the other hand, of course, with regard to the strength of the corona discharge by means of the corona discharger or the Corona discharge chamber 53 has a limitation in that the corona discharge must be safely operated without Spark discharge.

As a result of experiments based on the above-mentioned conditions, it was found that in order to restrict the fluctuation of the potential after the charge removal to 10 V or the like. the grid width i in relation to the direction of movement of the recording material should be greater than a value which is determined from the following equation: 4vdK / t (unit: mm); In this equation, the spacing d of the grid is given in mm, a value t / K which corresponds to the electrostatic capacity of the recording material such as the insulated drum and which is obtained by dividing the thickness t of the chargeable layer by its electricity

2'5 constant K is achieved, given in the unit Aim and the speed of the recording material in the unit cm / s. For example, if d = mm, t = 25 / im, K = 3 and ν = 40cm / s, the grid width 1 becomes Achieving an advantageous result about 40 mm ais Minimum and advantageously 50 mm determined. In this example, if the value of t is changed to 12 / µm, the Grating width 1 necessary to achieve the advantageous result is approximately 80 mm or more, i.e. preferably 100 mm. If the grid spacing d is changed to 1 mm, the grid width 1 can again be set to 40 mm and preferably mm can be reduced. In the example described above According to Fig. 7, it is possible to use a direct potential

809839/0797

-28- B 8803

Change from V ₁ to V to generate a positive corona discharge from the corona discharge or the corona discharge chamber 52 without using the corona discharge or the corona discharge chamber 53 With respect to the potential V _3, the potential directed towards the potential V ₁ and having a value V ₄ - V _{3 is} applied.

example

In the image forming apparatus or reproducing apparatus having the structure shown in FIG. 6, the corona discharger 38 has been replaced with a corona discharger having the structure shown in FIG. The control grid 19 shown in FIG. 1 was used as the control grid 19, which was obtained by applying a CdS resin dispersion layer as a photoconductive material to a base body in the form of a network of thin stainless steel wire with 10,000 meshes per cm ² (250 meshes per inch) and subsequent coating of an insulating material on the surface of the photoconductive material was made. The primary electrostatic charge image on this control grid had positive polarity which, when the surface potential at the bright portion of the image became -50 V under appropriate exposure, was converted to a state that did not allow any modulating ion current to pass through the control grid. From this state, the discharge conditions for the corona discharger 27 for applying the secondary voltage were changed so that the potential at the bright portion became -3OV. As a result of this process, an amount of current that corresponded to approximately 5% of the ionic current usually reaching the dark part of the image on the control grid could be conducted over the bright part of the image on the control grid. The developing device 36 for developing the secondary charge image was a magnetic brush device with magnetic toner, the brush of which

809839/0797

-29- B 8803

was partially earthed or connected to earth. If the secondary electrostatic charge image was thereby formed by. that the total surface potential of the insulated drum 32 was uniformly brought to about + 70V, no fogging could be perceived on the developed image. If at that _; actual example, a voltage of + 7kV was applied to the discharge electrode 52a of the corona discharger 51 and the surface potential V..of the insulated drum

: 32 was -200 V after it passed the image transfer corona charger shown in Fig. 6, the potential V ₂ became + 300V. To form the control grid 57 for the corona discharger 51, thin tungsten wire with a diameter of 0.1 mm was stretched at 1 mm intervals; the grid thus formed was then placed over the surface of the insulated drum 32 at a distance of 1 mm from the surface thereof. Then, when a voltage of +200 V was applied to the grid 57 and a voltage of -8 kV was applied to the discharge electrode 54 in the corona discharge chamber 53, the potential Vj became + 60V, so that the optimum condition without fogging could be obtained for the reproduced image. in which no ion stream passed through the control grid. In the state in which the bright portion of the primary electrostatic charge image was brought to -30V on the control grid drum, an electrostatic haze occurred. However, when the voltage applied to the grid 57 was changed from +200 to +22OV and the surface the isolated drum was uniformly charged to a potential of + 80V before the formation of secondary electrostatic charge image _r, the fog has been deleted on the developed .Figure from the secondary charge image, so that a clear image was obtained. On the other hand, when an original image with a background of light yellow, light blue or the like. was used, even if the secondary electrostatic charge image was formed using the primary electrostatic charge image formed under the same conditions, a very satisfactory reproduction image without fogging could be obtained

80 98 39/079 7

- 30 - B 8803

can similarly be achieved by keeping the voltage applied to the grid in the range of + 250V to +3 00V was increased. Further, even if the corona discharger, the control grid and other components of the reproduction machine their properties and operating states changed due to environmental fluctuations and changes over time, thereby changing the state of the primary electrostatic Charge pattern was also changed, the amount of change was within about 20V with respect to the Potential of the primary electrostatic charge image on the bright portion of the image. Because of this, I stepped myself in the event of a maximum change in the charge image potential in the negative direction, there is no position in which the image was erased, and by lowering the tension applied to the grid

voltage in a range of 180 to 200V a usable reproduced Image without haze can be achieved.

As described above, it is achieved by using the corona discharger with the grid device

the adjustment of the surface of the recording material a predetermined potential is possible under control of the potential applied to this grid device, which is determined by means of of the corona discharger applied to the recording material Adjust the charge potential so that the secondary electrostatic charge image on the recording material and so that the image state of the developed image is adjusted. In the case of an image forming apparatus without a developing device it is possible to achieve adjustment of the secondary electrostatic charge image.

In the image forming method, by adjusting the surface potential on the recording material, a Image correction possible if, when using a control grid suitable for repeat copying, the

809839/0797

- 31 - B 8803

occurs that the primary electrostatic charge image is weakened by the passage of the modulated ions, or if the strength of the modulated ion current passing through changes due to its weakening due to environmental changes changes. That is, the primary electrostatic charge image is not newly formed when it changes must be, the frequency of using the control grid can be reduced, resulting in an increase the durability or service life of the control grid. In conjunction with that for repeat copying appropriate control grid, therefore, the image forming method exhibits the above-mentioned effect. Further, the image forming method is Not only effective for repeat copying, but also for a control grid that just does for forming a secondary charge image once from an ordinary primary charge image once formed suitable is. For example, if the conditions in the formation of the primary electrostatic charge image are like the application of the amount of corona discharge, the amount of image exposure, and the like are set in advance, even at a deterioration of the control grid over the course of the period of use, with a background that is different from white of the original image or an increase or decrease in the ion current passing through due to changes the ambient conditions a necessary correction to Time of formation of the secondary electrostatic Charge image are made, whereby one of a Veil coloring of free secondary electrostatic charge image can be trained. That is, since it is sufficient to change the charging potential of the recording material without change To control the conditions in the formation of the primary electrostatic charge image, this will be Control procedures and the device structure are simplified. If

809839/0797

- - 32 - B 8803

furthermore, the image quality setting by means of the grating device of the corona discharger that has no contact with the chargeable material, there is no reason whatsoever to a concern about the occurrence of a short circuit between the element for application of the Voltage and the chargeable material, so that .therefore a possible damage to the surface of the chargeable material can be avoided.

In the above description, the image generation method was based on a particular embodiment explains in which an intermediate recording material for repeated use was used; the imaging process however, it can also be used in conjunction with a control grid 58 and a chargeable sheet 59 such as an electostatic one Recording paper can be used as the recording material as shown in FIG.

In this figure, 60 denotes a device for forming a primary electrostatic charge image,

61 a corona discharger that generates a modulating ion current,

62 a counter electrode for the corona discharger 61, 63 a Corona discharger with a grid with which the imaging process is performed, 63a a discharge electrode and 63b the grid. Rotates in the device shown the cylindrical control grid 5 3 in the direction of the arrow, while successively chargeable sheets 5 9 are transported in the direction of the arrow, the secondary being electrostatic The charge image on the recording sheet is later developed by means of a developing device (not shown). This means that a final image adjustment can be carried out by using before the ion current modulation the grid 63b of said corona discharger 63 the potential of the sheet 59 is set to a predetermined value. Regarding the copy required for repeat copying

809839/0797

- ■.;.; '" ^: "'; ν -33- '. ■ B 8803

Suitable control grid is not limited to that described in the preceding embodiment. Furthermore, repeat copying may or may not be enabled at will. Furthermore, the type of modulation arbitrary, i.e. there can of course be a modulation after the formation of the primary electrostatic charge image or a; Modulation at the same time as the development of the primary electrostatic charge image.

- ^: The present invention relates to an image forming method in which an ion current is modulated in the form of an image and as a result of which a secondary electrostatic charge image is formed on a recording sheet, an insulated drum or other recording material, which image is then developed. In detail, in the image forming method of the present invention, the total area of such a sheet.,; of such a drum or recording material S ₇ on which the secondary electrostatic charge image is formed is uniformly charged to a desired potential in advance, where fogging and changes in the formed image caused by changes in the image can be prevented from occurring during development Strength of the modulated ion current occur due to deterioration of an ion current modulating element.

The setting of the recording material for recording of the secondary electrostatic charge image to a desired, freely selectable potential can be, for example - ,. "" .. wise done by changing a voltage, which is attached to a grid installed in a corona discharger.

809839/0797

Claims (2)

Claims (jj Image generation method in which a Recording material directed ion current by means of a Ion current modulating element is modulated, whereby an electrostatic charge image is formed on the recording material is, characterized in that before the impact of the modulated ion current on the recording material carries out a uniform electrical charge thereon and that by setting the uniform charge potential the electrical potential of the to be formed on the recording material by means of the ion current modulation electrostatic charge image is set. 2. The method according to claim 1, characterized in, that the charge polarity for the charge of the recording material opposed to a uniform electrical potential is chosen for the polarity of the modulated ion current. IZT / Sc 00.9839 / 0797 -ir Bank (Munich) Account 3933 B-M Postal check (Munich) account 670-43-804